Muhammad Awais scite author profile

Transition metal dichalcogenides (TMDCs) are promising materials for sensing applications, due to their exceptional high performance in nano-electronics. Inherentely, the chemical and thermal responses of TMDCs are highly stable, hence, they pave way for real time sensor applications. This article proposes inceptively a stable and superfast humidity sensor using two-dimensional (2D) Molybdenum diselenide (MoSe 2) through printed technlogies. The 2D MoSe 2 ink is synthesized through wet grinding to achieve few-layered nano-flakes. Inter digital electrodes (IDEs) are fabricated via screen-printing on Polyethylene terephthalate (PET) substrate and thin film of MoSe 2 nano-flakes is fabricated through spin coating. The impedance and capacitance response are recorded at 1 kHz between temperature levels ranging from 20-30 °C. The impedance and capacitance hysteresis results are recorded <1.98% and <2.36%, respectively, ensuring very good repeatability during humidification and dehumidification. The stability of impedance and capacitance response are recorded with maximum error rate of ~ 0.162% and ~ 0.183%, respectively. The proposed sensor shows fast impedance response time (T res) of ~ 0.96 s, and recovery time (T rec) of ~ 1.03 s, which has T res of ~ 1.87 s, and T rec of ~ 2.13 s for capacitance. It is aimed to develop a high performance and stable humidity sensor for various monitoring applications.

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Humidity sensor based on Gallium Nitride for real time monitoring applications

Saqib

Khan

Awais

et al. 2021

Sci Rep

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Gallium Nitride (GaN) remarkably shows high electron mobility, wide energy band gap, biocompatibility, and chemical stability. Wurtzite structure makes topmost Gallium atoms electropositive, hence high ligand binding ability especially to anions, making it usable as humidity sensor due to water self-ionization phenomenon. In this work, thin-film GaN based humidity sensor is fabricated through pulse modulated DC magnetron sputtering. Interdigitated electrodes (IDEs) with 100 μm width and spacing were inkjet printed on top of GaN sensing layer to further enhance sensor sensitivity. Impedance, capacitance, and current response were recorded for humidity and bio-sensing applications. The sensor shows approximate linear impedance response between 0 and 100% humidity range, the sensitivity of 8.53 nF/RH% and 79 kΩ/RH% for capacitance and impedance, and fast response (Tres) and recovery (Trec) time of 3.5 s and 9 s, respectively. The sensor shows little hysteresis of < 3.53% with stable and wide variations for accurate measurements. Especially, it demonstrates temperature invariance for thermal stability. Experimental results demonstrate fabricated sensor effectively evaluates plant transpiration cycle through water level monitoring by direct attachment onto leaves without causing any damage as well as freshness level of meat loaf. These properties of the proposed sensor make it a suitable candidate for future electronics providing a low-cost platform for real time monitoring applications.

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All printed full range humidity sensor based on Fe2O3

Khan

Hassan

Awais

et al. 2020

Sensors and Actuators A: Physical

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All printed wide range humidity sensor array combining MoSe2 and PVOH in series

Khan

Awais

Chattha

et al. 2020

J Mater Sci: Mater Electron

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Optimal switching angles for minimization of total harmonic distortion in single phase cascaded multilevel inverters

Awais

Ilyas

Younus

et al. 2016

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Muhammad Awais

Printable Highly Stable and Superfast Humidity Sensor Based on Two Dimensional Molybdenum Diselenide

Humidity sensor based on Gallium Nitride for real time monitoring applications

All printed full range humidity sensor based on Fe2O3

All printed wide range humidity sensor array combining MoSe2 and PVOH in series

Optimal switching angles for minimization of total harmonic distortion in single phase cascaded multilevel inverters

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